Method of sensor wire count reduction

ABSTRACT

A method of sensor wire count reduction including receiving, from a sensor array comprising a first sensor, a second sensor, the third sensor, a first binary indication of sensor state for the first sensor a second binary indication of sensor state for the second sensor, and a third binary indication of sensor state for the third sensor. The method further includes setting a first voltage in response to the first binary indication of sensor state for the first sensor and the second binary indication of sensor state for the second sensor, determining a first indication comprising whether the fist voltage is within a first range, determining a second indication comprising whether the first voltage is within a second range, and determining a third indication comprising whether the first voltage is within a third range.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a divisional application of, and claims priority to,U.S. application Ser. No. 14/291,391, filed May 30, 2014 and titled“SENSOR WIRE COUNT REDUCTION SYSTEM,” which is hereby incorporated byreference in its entirety.

FIELD

The present invention relates to the field of sensors. Moreparticularly, the present invention relates to a system forcommunicating data from motor position sensors.

BACKGROUND

Aircraft have utilized various motor position sensor systems to providecommutation for different motors, for example, brake actuator motors.Often various control components are connected to the brake actuatormotors and the motor position sensor systems by cables. Often, a sensoris connected to other systems by a dedicated mechanism, forcommunicating electronic information such as a sensor signal. Often thisdedicated mechanism is a dedicated wire within a cable. Thus, eachsensor often requires its own wire.

SUMMARY OF THE INVENTION

In accordance with various aspects of the present invention, a method ofsensor wire count reduction is disclosed. A method of sensor wire countreduction may include receiving, from a sensor array comprising a firstsensor, a second sensor, and third sensor, a first binary indication ofsensor state for the first sensor, a second binary indication of sensorstate for the second sensor, and a third binary indication of sensorstate for the third sensor. The method may further include setting afirst voltage in response to the first binary indication of sensor statefor the first sensor and the second binary indication of sensor statefor the second sensor, determining a first indication comprising whetherthe first voltage is within a first range, determining a secondindication comprising whether the first voltage is within a secondrange, and determining a third indication comprising whether the firstvoltage is within a third range.

In various embodiments, the method of sensor wire count reduction mayfurther comprise combining the first indication and the thirdindication, combining the first indication and the second indication,providing a first output in response to the combining the firstindication and the third indication, providing a second output inresponse to the combining the first indication and the secondindication. The first output may indicate a state of the first sensor,and wherein the second output indicates a state of the second sensor.The method may further comprise setting a second voltage in response tothe third binary indication of sensor state for the third sensor,determining a forth determination comprising whether the second voltageis within a forth range, and providing a third output in response to thedetermining a forth determination. The method may further comprisedetermining by a pulse decoder a frequency of activation of the firstsensor, the second sensor, and the third sensor. The first sensor, thesecond sensor, and the third sensor may comprise Hall Effect sensors.

BRIEF DESCRIPTION OF THE DRAWINGS

A more complete understanding of the present invention may be derived byreferring to the detailed description and claims when considered inconnection with the Figures, where like reference numbers refer tosimilar elements throughout the Figures, and:

FIG. 1 depicts a diagram of an exemplary embodiment of a sensor systemhaving a cable with reduced wire count;

FIG. 2 depicts various aspects of an exemplary embodiment of a sensorsystem;

FIG. 3 depicts a chart illustrating various signals and states of asensor system;

FIG. 4 depicts a detailed schematic diagram of an exemplary embodimentof a sensor system; and

FIG. 5 depicts an exemplary method of sensor wire count reduction.

DETAILED DESCRIPTION

The following description is of various exemplary embodiments only, andis not intended to limit the scope, applicability or configuration ofthe present disclosure in any way. Rather, the following description isintended to provide a convenient illustration for implementing variousembodiments including the best mode. As will become apparent, variouschanges may be made in the function and arrangement of the elementsdescribed in these embodiments without departing from the scope of theappended claims.

For the sake of brevity, conventional techniques for manufacturing andconstruction may not be described in detail herein. Furthermore, theconnecting lines shown in various figures contained herein are intendedto represent exemplary functional relationships and/or physicalcouplings between various elements. It should be noted that manyalternative or additional functional relationships or physicalconnections may be present in a practical method of construction.

With reference to FIG. 1, a sensor wire count reduction system 2 ispresented. A sensor wire count reduction system 2 comprises a sensorapparatus 4, a transmission cable 6, and a controller 8.

A sensor wire count reduction system 2 may reduce the number of wiresutilized to communicate with a given number of sensors versus systemswherein each sensor communicates with other systems via a dedicatedmechanism, such as a dedicated wire. For example, in various instances,a sensor wire count reduction system 2 may be implemented with threesensors which otherwise would each require one data wire each. However,the sensor wire count reduction system 2 can combine signals frommultiple sensors onto a single wire. In this way, the sensor wire countreduction system 2 decreases the number of wires include in cablingbetween the sensors and a remote device, such as a controller. Thus, thesensor wire count reduction system 2 decreases the number of wires to beincluded in transmission cable 6.

In various embodiments, a sensor apparatus 4 comprises a sensor array10, and a sensor encoder 12. The sensor array 10 may be a number ofsensors disposed proximate to a component being sensed. For example, thesensor array 10 may comprise position sensors. In various embodiments,the sensor array 10 comprises at least two Hall Effect sensors.Furthermore, the sensor array 10 may comprise three Hall Effect positionsensors, or may comprise four sensors, or may comprise any number ofsensors. In various embodiments, the sensor array 10 comprises threesensors evenly disposed about the circumference of a motor. In thismanner, the sensor array 10 may sense the position of the motor shaft,for example, to provide commutation to the motor, or to determine motorshaft position, or to determine motor shaft speed. Thus, as illustratedin FIGS. 1 and 2, a sensor array 10 may comprise a Sensor A 23, a SensorB 24, and a Sensor C 25. Sensor A 23 may be disposed 120 degrees fromSensor B 24 and Sensor C 25, and Sensor B 24 may be disposed 120 degreesfrom Sensor A 23 and Sensor C 25, so that the sensors are positioned 120degrees apart about a motor for which sensing is to be provided.

A sensor apparatus 4 may comprise a sensor encoder 12. With reference toFIG. 1, the sensor encoder 12 may be in electrical communication withthe sensor array 10. As used herein, electrical communication may referto any electrical, electromagnetic, radiofrequency and/or optical methodwhereby information may be conveyed. The sensor encoder 12 may receivesignals from the sensor array 10. In various embodiments, each sensor(Sensor A 23, Sensor B 24, Sensor C 25) provides a binary output (e.g.,a high or low voltage or a digital signal of a 0 or 1) indicative ofwhether that sensor is triggered or is not triggered. The binary outputof some or all of the sensors in sensor array 10 is input to the sensorencoder 12. In various embodiments, sensor encoder 12 may be adapted toreceive signals from multiple sensors.

In various embodiments, the sensor encoder 12 permits a portion of thesignals to pass directly through without processing, for example, withreference to FIG. 2, sensor encoder 12 may comprise a level pass-through28. A level pass-through 28 may comprise an electrical or logicalmechanism, such as a wire, whereby a signal, for example, from Sensor A23, may pass through without processing. The sensor encoder 12 may alsohave a level setter 26.

As will be discussed further herein, some or all of the sensors ofsensor array 10 may be in electrical communication with the level setter26 component of the sensor encoder 12. With reference to both FIGS. 1and 2, the sensor apparatus 4, including the level setter 26, may be inelectrical communication with a transmission cable 6. In this manner,signals may be conveyed from the sensor array 10, to other components ofthe sensor apparatus 4, such as the sensor encoder 12, after which theymay be conveyed to a transmission cable 6 for conduction to othersystems or system components.

A transmission cable 6 may comprise a multiple conductor cable.Alternatively, a transmission cable 6 may comprise an assembly ofseparate individual conductors. Furthermore, a transmission cable 6 maycomprise shielding elements, and may comprise conductors of differentgauges. In various embodiments, the transmission cable 6 comprises amulti-level signal wire 14 in electrical communication with the levelsetter 26 of the sensor encoder 12. Similarly, the transmission cable 6may comprise a single-level signal wire 16 in communication with thelevel pass-through 28 of the sensor encoder 12. The transmission cable 6may also conduct power to various aircraft systems and devices,including components of the sensor wire count reduction system 2.Accordingly, the transmission cable 6 may further comprise multiplepower wires, for instance, a power wire 18-1 and a power wire 18-2.Still furthermore, a transmission cable 6 may not be a standalone cable,but may be a logical subset or portion of a larger cable or cablesystem.

A level pass-through 28 may comprises a logical and/or electricalconnection through the sensor encoder 12 whereby signals may betransmitted to the transmission cable 6 without encoding or decoding.Some signals may remain on their own channels, for instance, Sensor A 23may be logically and/or electrically connected to single-level signalwire 16 of transmission cable 6.

A multi-level signal wire 14 may comprise an electrical and/or logicalconnection whereby multiple signal levels may be encoded. However, amulti-level signal wire 14 may not be an actual wire, but may comprisean RF or optical link, or may comprise a logical communication layer,bus, or protocol, or may comprise any other mechanism of conveyingelectronic information.

A single-level signal wire 16 may comprise an electrical and/or logicalconnection whereby multiple signal levels may be encoded. However, asingle-level signal wire 16 may not be an actual wire, but may comprisean RF or optical link, or may comprise a logical communication layer,bus, or protocol, or may comprise any other mechanism of conveyingelectronic information.

The transmission cable 6 may conduct signals to a controller 8. Acontroller 8 may be disposed at some distance from the sensor apparatus4. For example, the sensor apparatus 4 may be located proximate to anaircraft brake actuation motor while the controller 8 may be locatedwithin the aircraft fuselage, for example, proximate to a controller, ora computer, or a power source.

With reference to FIGS. 1 and 2, a controller 8 may comprise amultilevel to binary decoder 20 and outputs 22-1, 22-2, and 22-3. Invarious embodiments, the controller 8 optionally comprises a pulsedecoder 50. The controller 8 may provide processed output data inresponse to the sensors. The controller 8 may process the signals fromthe transmission cable 6 and create output indicative of the state ofthe sensor array 10. The controller 8 may be located at a remotedistance from the sensor apparatus 4, and connected by transmissioncable 6.

A multi-level to binary decoder 20 may be in electrical communicationwith the multi-level signal wire 14. The multi-level signal wire 14 mayprovide a multi-level signal, which the multi-level to binary decoder 20then converts to multiple binary signals. Thus, the data provided fromSensor A 23, Sensor B 24, and Sensor C 25 may be decoded and separatelyoutput on separate outputs 22-1, 22-2, and 22-3.

Outputs 22-1, 22-2, and 22-3 may comprise binary outputs. Each outputmay indicate a high or low voltage in response to a high or low binarystate. In various embodiments, each sensor is mapped to a differentoutput. Sensor A 23 may be mapped to Output 22-1, Sensor B 24, may bemapped to Output 22-2, and Sensor C 25 may be mapped to Output 22-3. Theoutput may be represented as a three-bit binary number, or the outputmay be thought of as an array of wholly separate channels of data.Moreover, in various embodiments, one or more sensors, such as Sensor A23, are in direct communication with an output and/or the multi-level tobinary decoder 20, without passing through the level setter 26 of thesensor encoder 12, but rather passing through level pass-through 28 ofthe sensor encoder 12, then connected via single-level signal wires 16of the transmission cable 6 to the controller 8, for example, as SensorA 23 is mapped to Output 22-1 and passes directly through to it.

As indicated previously, the controller 8 may comprise a pulse decoder50 that may be an apparatus that counts level transitions (e.g., changesin the voltage of the signal) received at the multi-level to binarydecoder 20. In this manner, the pulse decoder 50 may indicate thefrequency of sensor activation. For example, if the sensors areimplemented to facilitate motor commutation or to evaluate motor speedor motor position, then the pulse decoder 50 may provide an indicationof each level transition. Accordingly, the revolutions per minute (RPM)of the motor may be indicated by the pulse decoder 50. The pulse decoder50 may comprise a pulse decoder output 52 where this indication isprovided. In various embodiments, the pulse decoder output 52 provides asquare wave in response to the frequency of sensor activation, though itmay provide pulses, or a triangle wave, or a saw tooth wave, or a seriesof impulse transients or any other output indicative of sensoractivation.

With focus on FIGS. 1, 2, and 4, a sensor array 10 may comprise a SensorA 23, a Sensor B 24, and a Sensor C 25, as previously discussed. Asensor array 10 may comprise similar or different sensors. In variousembodiments, a sensor array 10 comprises all Hall Effect sensors, thoughin other embodiments, a sensor array 10 may comprise a combination ofdifferent sensors, for example Hall Effect sensors, mechanical switches,reed switches, or capacitive proximity sensors, or any other sensor ornumber of sensors adapted for a particular purpose.

A sensor encoder 12 may comprise a level setter 26. A level setter 26may comprise an electronic circuit whereby the binary state of sensors,for example, Sensor B 24 and Sensor C 25 are converted into amulti-state signal. For instance, a voltage divider circuit may beimplemented whereby different voltages are output depending on thedifferent states of Sensor B 24 and Sensor C 25. Sensor B and Sensor C25 may each comprise a switch, for example a Hall Effect sensor. Inresponse to a sensor indicating a “HI” binary state, the sensor mayconduct electricity and in response to a sensor indicating a “LO” binarystate, the sensor may be non-conductive. Different legs of the voltagedivider circuit may be made conductive or non-conductive and a sourcevoltage may be divided in different ways. In this manner, the voltagedivider circuit may be implemented to provide different output voltagesdepending on the different conduction states of Sensor B 24 and Sensor C25.

In various embodiments, each sensor further comprises a transistor. Forexample, in various embodiments, a sensor, for example, a Hall Effectsensor, may control the gate of a transistor, for example a field-effecttransistor comprising a selectably conductive path. In variousembodiments, the gate voltage of the transistor may be pulled HI or LOin response to the sensor detecting an event. Accordingly, thefield-effect transistor may be a p-channel FET, or an n-channel FET.Alternatively, other transistors such as BJTs, whether NPN or PNP, maybe implemented, or in some embodiments, for example, if the Hall Effectsensors have sufficient current capacity, no transistors at all may beimplemented, but the Hall Effect sensors may provide the conductionpaths without a transistor, rather than comprising transistors or othervoltage-controlled switches or other current-controlled switches.

Various current limiting resistors may be selected for the differentconduction paths of the voltage divider, causing different voltages tobe present at the output of the voltage divider, depending on thecombination of conduction paths which are conducting at any time (e.g.,depending on the HI/LO state of the Hall Effect sensors). In variousembodiments, the selected components are of the values reflected in FIG.4. The level setter 26 may be in electrical communication with themulti-level signal wire 14 of the transmission cable 6 (FIG. 1). In thismanner, the different voltages may be conducted to a controller 8(FIG. 1) for decoding.

In various embodiments, the level setter 26 may set any number of outputstates (e.g. voltage levels). For example, a level setter 26 may be incommunication with two sensors, Sensor B 24 and Sensor C 25. Each sensormay have two states, on and off (e.g., HI and LO). Thus, level setter 26may have four possible output states. As one may appreciate, a levelsetter 26 in communication with bi-state sensors may have 2^n states,where n is the number of sensors. Further generalized, a level setter 26may have x^n states wherein the level setter 26 is in communication withN x-state sensors. A level setter 26 may comprise any circuitry wherebyseparate channels of data (e.g., sensors) are combined on a singlechannel of data (e.g., multi-level signal wire 14).

With specific reference to FIGS. 1 and 2, a multi-level to binarydecoder 20 may comprise a thresholder and a combiner. The multi-level tobinary decoder 20 may comprise multiple thresholders, for exampleThresholder A 30-1, Thresholder B 30-2, Thresholder C 30-3, andThresholder D 30-4. Each thresholder may be configured to determinewhether the multi-level signal wire 14 is indicating a voltage above orbelow a given threshold. By implementing multiple thresholders, multiplesuch thresholds may be assessed. In various embodiments, eachthresholder indicates a binary state in response to the determination ofwhether the signal is above or below the threshold (for example,Thresholder D 30-4), or may provide a binary state in response to thedetermination of whether the signal is within a threshold range oroutside a threshold range (for example, Thresholder A 30-1, ThresholderB 30-2, and Thresholder C 30-3).

The multi-level to binary decoder 20 may further comprise combiners thatcombine this state information arising from determinations made bymultiple thresholders. For example, a multi-level to binary decoder 20may comprise multiple combiners. For example, Combiner B 34-2 maycombine outputs from Thresholder A 30-1 and Thresholder B 30-2.Similarly, Combiner C 34-3 may combine outputs from Thresholder A 30-1and Thresholder C 30-3. Still furthermore, Combiner D 34-4 may combinean output from Thresholder D 30-4 with itself, for example, for delay,isolation, and/or signal conditioning, rather than actual combination ofsignals. Similarly, Combiner A 34-1 may combine an output fromThresholder A 30-1 with a delayed (via delay circuitry 32) output fromThresholder A 30-1 to ameliorate noise. The combiners may combinevarious outputs of various thresholders.

An embodiment of the interconnection of thresholders and combiners isshown in FIG. 2. For example, Thresholder C 30-3 and Thresholder A 30-1may both provide binary output signals indicative of whether amulti-level signal provided on multi-level signal wire 14 (FIG. 1) isinside or outside of various ranges. The binary output signal ofThresholder A 30-1 and Thresholder C 30-3 may be provided to Combiner C34-3. The Combiner C 34-3 may provide a binary output signal to Output22-2. A combiner may comprise a logical-OR operation, for instance, asperformed by an OR gate, so that a HI is indicated if any thresholderconnected to it indicates a HI state. For example, Combiner C 34-3 mayindicate a HI state if either of Thresholder C 30-3 and Thresholder A30-1 indicate a HI, for instance, in the event that a multi-level signalprovided on multi-level signal wire 14 is within a range assessed byeither of Thresholder C 30-3 or Thresholder A 30-1.

Similarly, Thresholder B 30-2 and Thresholder A 30-1 may beinterconnected with Combiner B 34-2. Still furthermore, Thresholder D30-4 may be interconnected with Combiner D 34-4, but without any otherthresholder. Thresholder D 30-4 may be combined with itself so that thesignal may be conditioned and provided to output 22-1. Combiner D 34-4may simply condition the signal to have similar characteristics commonwith the signals provided to output 22-2 and output 22-3 that have beencombined via combiners.

With reference to FIGS. 2 and 4, in various embodiments, a thresholdermay comprise a pair of OP-AMP comparators. Each may be provided with adifferent reference voltage. The OP-AMPs may thus be configured toprovide an output indication of whether an input voltage falls betweenthe two reference voltages, or falls outside the two reference voltages.Alternatively, a thresholder may comprise a single OP-AMP comparatorprovided with a reference voltage in order to provide an outputindication of whether the input voltage falls above or below thereference voltage. In this manner, the thresholder may decodeinformation. An embodiment of various threshold voltages and componentvalues is indicated in FIG. 4.

In various embodiments, delay circuitry 32 may be implemented inconnection with thresholders and combiners. For example, at variouspoints it may be desirable to delay signals entering the combiners 34,for example, to ensure that state transitions are properly timed or toensure that race states are avoided. As illustrated in FIG. 2, a delaycircuitry 32 may be disposed between Thresholder A 30-1 and Combiner A34-1. In this manner, it may be ensured that components have ampleprocessing time to permit signals to propagate. In this manner, unwantedtransient changes, such as race states at various outputs, for exampleOutput 22-2 and/or Output 22-3 and/or the pulse decoder output 52 may beameliorated.

Pulse decoder 50 may comprise logical gates and filtering components.For example, pulse decoder 50 may comprise inverters and diodes. Invarious embodiments, two inverters are implemented with a diode filterdisposed between the inverters. Pulse decoder 50 may provide a pulsedecoder output 52, which is filtered by the diodes and invertors, aswell as delayed so that the pulse decoder output 52 is substantiallysynchronous with the outputs 22-1, 22-2, and 22-3. An example embodimentof a pulse decoder 50 is illustrated in FIG. 4.

Having discussed various aspects of a sensor wire count reduction system2, attention is now directed to FIGS. 2-4, but with particular emphasison FIG. 3, which illustrates various different states of a sensor wirecount reduction system 2. As reflected in FIG. 3, a ‘0’ and a ‘1’represent different binary states. As one can appreciate, the outputsreflect states equivalent to those of the sensors. Output 22-1 mayreflect Sensor A 23, Output 22-2 may reflect Sensor B 24, and Output22-3 may reflect Sensor C 25. As previously discussed, Sensor B 24 andSensor C 25 are connected to the level setter 26, thus the level setter26 may also have different logical states in response to the states ofSensor B 24 and Sensor C 25. These states may be assigned numbers, forexample zero through four as shown in the FIG. 3. In each such state,the level setter 26 may provide a signal on the multi-level signal wire14 of the transmission cable 6. More specifically, the level setter 26may set a voltage on the multi-level signal wire 14. The level setter 26may be configured to ensure that each voltage corresponding to a statelies within a different range corresponding to the threshold ranges ofthe thresholders comprising the controller 8. These ranges may includeV₀-V₁, V₂-V₃, V₄-V₅, V₆-V₇, as illustrated in FIG. 3, and implemented inFIG. 4. In various embodiments, V₀₋₇ comprise voltages defined in FIG.4. In various embodiments, the ranges are chosen to accommodate voltagedrop and/or noise, for example, that which may occur across transmissioncable 6.

While the systems described herein have been described in the context ofaircraft applications; however, one will appreciate in light of thepresent disclosure, that the systems described herein may be used invarious other applications, for example, different vehicles, differentsensor applications, and different signal transmission arrangements, orany other vehicle or device, or in connection with industrial processes,or propulsion systems, or any other system or process having need forsensor wire count reduction.

Moreover, a sensor wire count reduction system 2 may operate accordingto various methods. For example, with additional reference to FIG. 5, amethod 100 may include wherein the sensor encoder 12 receives from asensor array 10, a binary indication of sensor state for a first sensor(Sensor A 23), a second sensor (Sensor B 24) and a third sensor (SensorC 25) (Step 102). The sensor encoder 12 may set a first voltage (e.g.state of level setter 26) in response to a binary indication for sensorstate for the second sensor (Sensor B 24) and a binary indication ofsensor state for the third sensor (Sensor C 25) (Step 104). This voltagemay be put on the multi-level signal wire 14 and conveyed to the binarydecoder 20. Then, the binary decoder 20 may determine a first indicationcomprising whether the voltage is within a first range, a secondindication comprising whether the first voltage is within a secondrange, or a third indication comprising whether the first voltage iswithin a third range (Step 106). These determinations are made atthresholders 30-1, 30-2, and 30-3 as discussed herein. Subsequently thecombiners 34-1, and 34-2 may combine certain of the determinations ofindications (e.g., HI/LO status indications) as discussed herein (Step108). Finally, the combiners provide outputs, for example Output 22-2and Output 22-3 (Step 110). Combiner C 34-3 may combine the firstindication and the third indication and Combiner B 34-2 may combine thefirst indication and the second indication (Step 108). Combiner C 34-3may provide Output 22-2 in response to the combining the firstindication and the third indication and Combiner B 34-2 may provideOutput 22-3 in response to the combining the first indication and thesecond indication (Step 110). Output 22-1 may be provided in response toSensor A 23 alone, and thus may not be combined with other sensorindications. Rather, a second voltage may be set in response to a binaryindication for Sensor A 23 alone and determined whether it is in afourth range by a thresholder 30-4. A third output, Output 22-1 may beprovided in response.

Benefits, other advantages, and solutions to problems have beendescribed herein with regard to specific embodiments. Furthermore, theconnecting lines shown in the various figures contained herein areintended to represent exemplary functional relationships and/or physicalcouplings between the various elements. It should be noted that manyalternative or additional functional relationships or physicalconnections may be present in a practical system. However, the benefits,advantages, solutions to problems, and any elements that may cause anybenefit, advantage, or solution to occur or become more pronounced arenot to be construed as critical, required, or essential features orelements of the inventions. The scope of the inventions is accordinglyto be limited by nothing other than the appended claims, in whichreference to an element in the singular is not intended to mean “one andonly one” unless explicitly so stated, but rather “one or more.”Moreover, where a phrase similar to “at least one of A, B, or C” is usedin the claims, it is intended that the phrase be interpreted to meanthat A alone may be present in an embodiment, B alone may be present inan embodiment, C alone may be present in an embodiment, or that anycombination of the elements A, B and C may be present in a singleembodiment; for example, A and B, A and C, B and C, or A and B and C.

Systems, methods and apparatus are provided herein. In the detaileddescription herein, references to “various embodiments”, “oneembodiment”, “an embodiment”, “an example embodiment”, etc., indicatethat the embodiment described may include a particular feature,structure, or characteristic, but every embodiment may not necessarilyinclude the particular feature, structure, or characteristic. Moreover,such phrases are not necessarily referring to the same embodiment.Further, when a particular feature, structure, or characteristic isdescribed in connection with an embodiment, it is submitted that it iswithin the knowledge of one skilled in the art to affect such feature,structure, or characteristic in connection with other embodimentswhether or not explicitly described. After reading the description, itwill be apparent to one skilled in the relevant art(s) how to implementthe disclosure in alternative embodiments.

Furthermore, no element, component, or method step in the presentdisclosure is intended to be dedicated to the public regardless ofwhether the element, component, or method step is explicitly recited inthe claims. No claim element herein is to be construed under theprovisions of 35 U.S.C. 112(f), unless the element is expressly recitedusing the phrase “means for.” As used herein, the terms “comprises”,comprising”, or any other variation thereof, are intended to cover anon-exclusive inclusion, such that a process, method, article, orapparatus that comprises a list of elements does not include only thoseelements but may include other elements not expressly listed or inherentto such process, method, article, or apparatus.

The invention claimed is:
 1. A method of sensor wire count reductioncomprising: receiving, from a sensor array comprising a first sensor, asecond sensor, and third sensor, a first binary indication of sensorstate for the first sensor, a second binary indication of sensor statefor the second sensor, and a third binary indication of sensor state forthe third sensor; setting a first voltage in response to the firstbinary indication of sensor state for the first sensor and the secondbinary indication of sensor state for the second sensor; determining afirst indication comprising whether the first voltage is within a firstrange; determining a second indication comprising whether the firstvoltage is within a second range; and determining a third indicationcomprising whether the first voltage is within a third range.
 2. Themethod of sensor wire count reduction according to claim 1, furthercomprising: combining the first indication and the third indication;combining the first indication and the second indication; providing afirst output in response to the combining the first indication and thethird indication; providing a second output in response to the combiningthe first indication and the second indication.
 3. The method of sensorwire count reduction according to claim 2, wherein the first outputindicates a state of the first sensor, and wherein the second outputindicates a state of the second sensor.
 4. The method of sensor wirecount reduction according to claim 3, further comprising: setting asecond voltage in response to the third binary indication of sensorstate for the third sensor; determining a forth determination comprisingwhether the second voltage is within a fourth range; and providing athird output in response to the determining a forth determination. 5.The method of sensor wire count reduction according to claim 4, furthercomprising determining by a pulse decoder a frequency of activation ofthe first sensor, the second sensor, and the third sensor.
 6. The methodof sensor wire count reduction according to claim 1, wherein the firstsensor, the second sensor, and the third sensor comprise Hall Effectsensors.